DE10014665B4 - Method for protecting a matrix converter from overvoltages and an active overvoltage device - Google Patents

Abstract

A method of protecting a matrix inverter (28) from overvoltages with nine bidirectional power switches (2) arranged in a 3x3 switch matrix, either
- from all input and output potentials ( 7 ) or
- in each case from all input and output potentials ( 9 ) or
- each of all input potentials and one of the three output potentials ( 11 )
a maximum potential is determined, wherein when exceeding a predetermined limit, the bidirectional power switch (2) of the matrix converter (28) are driven.

Description

The The invention relates to a method of protecting a matrix converter with nine in a 3x3 switch matrix arranged bidirectional circuit breakers against surges and an active overvoltage protection device.

at a matrix converter is a self-commutated direct converter. This self-guided Direct converter is a converter without DC link. By the Arrangement of power electronic switches in a 3 × 3 switch matrix the three input phases are connected to the three output phases. This self guided Direct converter has the advantage that it depends on the topology is capable of regenerative feedback and achieved by a correspondingly pronounced control sinusoidal mains currents. As a bidirectional switch of the switch matrix can on the one hand one in a diode bridge integrated semiconductor switch and on the other two antiserial switched semiconductor switches are used. The two antiserial switched semiconductor switch of a bidirectional circuit breaker the switch matrix are either in the topology "common emitter mode" or "common collector Mode " embodiment of the bidirectional power switch, wherein a semiconductor switch in a diode bridge embedded is called "Embedded Switch ".

The circuit diagram of a bidirectional switch 2 in the topology "common collector fashion" is in the 1 shown in more detail. The 2 shows a bidirectional power switch for comparison 2 in the topology "Common Emitter Mode". These two bidirectional circuit breakers 2 each have two semiconductor switches 4 and 6 on, which are antiserial switched. In the 1 are these two semiconductor switches 4 and 6 switched so antiserial that the two collector terminals are electrically connected to each other. Therefore, this antiserial circuit of the two semiconductor switches 4 and 6 also referred to as "common collector mode". In the 2 are the two semiconductor switches 4 and 6 switched so antiserial that their emitter terminals are electrically connected. According to the connection of the emitter terminals, this interconnection is referred to as a "common emitter mode". As a semiconductor switch 4 and 6 switchable semiconductor switches, in particular insulated gate bipolar transistors (IGBT) are used, each having a reverse diode. At the accessible terminals of the bidirectional circuit breaker 2 you can recognize the internal topology. With the bidirectional circuit breaker 2 in the topology "Common Collector Mode" according to 1 are at the circuit breaker 2 the terminals E1, E2, G1 and G2 accessible. In contrast, the bidirectional circuit breaker 2 in the topology "Common Emitter Mode" according to 2 the terminals C1, C2, G1 and G2 accessible. In addition, these bidirectional power switches exhibit 2 Auxiliary terminals EH1 and EH2, each forming a control terminal.

In the 3 is a circuit diagram of a bidirectional circuit breaker 2 in the topology "embedded switch" in more detail. This bidirectional circuit breaker 2 has a turn-off semiconductor switch 5 , in particular an insulated gate bipolar transistor (IGBT), which is arranged in a diode bridge. This semiconductor switch 5 is the collector side electrically connected to cathode terminals of two diodes and emitter side with anode terminals of two other diodes of the diode bridge. The free terminals of these diodes each form an input and output terminal of the bidirectional power switch 2 ,

By driving the semiconductor switch 4 and 6 or the semiconductor switch 5 of the bidirectional circuit breaker 2 of the matrix converter, a current path in each case is switched through in a specific direction. Are both semiconductor switches 4 and 6 triggered, then a current flow in both directions is made possible, so that a secure electrical connection between an input and an output phase takes place. Is with a bidirectional circuit breaker 2 in the topology "common collector mode" or "common emitter mode" only one semiconductor switch 4 respectively. 6 of the bidirectional circuit breaker 2 controlled by the matrix converter, then this connection arises only for a preferred current direction. One phase of the matrix converter is an arrangement of three bidirectional power switches that connects each of the three network phases to one of the output phases.

There the matrix converter has no passive free-wheeling circuits, such as a Voltage DC Inverter, occur in particular in the case of due to an EMERGENCY STOP generated pulse inhibit (switching off the Drive pulses of all semiconductor switches) due to the in the circuit existing inductors high Blocking voltage on the semiconductor switches on. These surges can also due to failure of the control of bidirectional circuit breakers occur. In these cases mentioned Each time the output current is interrupted. The interruption of the output circuit in conjunction with those present in the circuit inductors causes the surges, the destruction According to the semiconductor switch may have.

From the Novel Solutions for Protection of Matrix Converter to Three Phase Induc An overvoltage protection device is known, "tion Machine", published in the conference proceedings "IEEE Industry Applications Society" New Orleans, Louisiana, October 5-9, 1997, pages 1447 to 1454. This overvoltage protection device has two 6-pulse diode bridges, the DC side by means of a capacitor On the AC side, one 6-pulse diode bridge is connected to the input terminals of the matrix inverter, the other diode bridge is connected to the output terminals of the matrix inverter on the AC side The input terminals of the matrix inverter are also connected to an LC filter connected on the input side to a three-phase network.This LC filter, also referred to as an input filter, keeps pulse frequency harmonics away from the mains.The size of this filter depends on the pu frequency of the matrix converter.

Occurring surges be through the diode bridges rectified and placed on the capacitor. For this overvoltage protection device, which is also the subject of US Patent 4,697,230 is, a precharge circuit for the capacitor is needed. These Precharge circuit is needed so that when switching on the matrix converter no inrush current peaks or high voltages of double mains voltage occur. Such surges cause high peak currents, that of the diodes of the diode bridge be guided have to. The resistor is dimensioned so that the capacitor is around one predetermined amount of energy is discharged.

Out the nearest one Prior Art Publication "Performance of a Two Steps Commutated Matrix Converter for AC Variable Speed Drives ", printed in the proceedings EPE'99, Lausanne, September 1999, pages 1 to 9, is also an overvoltage protection device known, which has two 6-pulse diode bridges, wherein from all Input and output potentials determines a highest potential becomes. Each of these two diode bridges has DC voltage side a capacitor on. These two capacitors are electric connected in parallel. A zener diode and a pulse resistor are electrically connected in parallel with these two capacitors, with which the voltage of the capacitors to a predetermined value is limited. In addition, points Each bidirectional power switch has one varistor and two antiseries switched Zener diodes, with which the overvoltages at bidirectional Circuit breakers are limited.

In the publication "A Matrix Converter without Reactive Clamp Elements for an Induction Motor Drive System ", by Mr. Axel Schuster, printed in IEEE, 1998, pages 714 to 720, are used as overvoltage protection devices several varistors provided. Each semiconductor switch each bidirectional Circuit breaker of the 3 × 3 switch matrix a varistor is electrically connected in parallel. These varistors protect the 18 semiconductor switches of the nine bidirectional power switches against surges.

at the use of this overvoltage protection device must when bidirectional circuit breaker in common collector Mode of connection of the two collector terminals of the be led out two antiseries switched semiconductor switch. It is also possible, that the bidirectional power switch from individual semiconductor devices is constructed. Only when the collector connections or their connection point accessible are, can Each semiconductor switch of a bidirectional circuit breaker a varistor are electrically connected in parallel.

From the publication "Wiring of SIPMOS transistors", printed in the "Siemens Components", Volume 22, Issue 4, 1984, pages 157 to 159, a voltage clamping circuit is known. This voltage clamping circuit is in the 4 at a semiconductor switch 4 shown in more detail and is with 8th characterized. This voltage clamping circuit 8th consists of a zener diode 10 , in particular a high-voltage zener diode, which is also referred to as a transiode diode, and a decoupling diode 12 , This voltage clamping circuit 8th is between collector terminal C and gate terminal G of the semiconductor switch 4 connected. As a semiconductor switch 4 For example, an insulated gate bipolar transistor (IGBT) with a reverse diode is provided. The decoupling diode 12 disconnects the voltage clamping circuit 8th from the gate terminal G of the semiconductor switch 4 when the semiconductor switch is turned on 4 from. Once in the locked state, the semiconductor switch 4 its collector-emitter voltage is the sum of the Z-voltage of the transiode diode, the threshold voltage of the decoupling diode 12 and exceeds the gate-emitter threshold voltage, the semiconductor switch 4 controlled automatically. Thus, an occurring overvoltage on the semiconductor switch 4 actively limited by this, but in the semiconductor switch 4 and in the transiodiode 10 Losses occur.

This active overvoltage protection device can be connected directly to a bidirectional power switch in the "common emitter mode" topology. 2 ) be used. That is, each of the two semiconductor switches 4 and 6 of the bidirectional circuit breaker 2 in common emitter mode becomes a voltage clamp circuit 8th electrically parallel switched to the collector-gate path. This can also be realized without much effort, since the required connections - collector terminal C and gate terminal G - are accessible.

A use of this known voltage clamping circuit 8th in a bidirectional circuit breaker in common collector mode is not readily possible. For this to be possible, the common collector connection must be made from the bidirectional power switch 2 be led out.

Of the The invention is based on the object, a matrix converter economical and little effort against overvoltages to protect.

These Task is according to the invention with the Characteristics of the independent Claim 1 solved.

With the method according to the invention will be first detects the presence of an overvoltage that occurs then all endangered bi-directional circuit breaker of the matrix converter automatically controls. This can cause this overvoltage Do not destroy a bidirectional circuit breaker of the matrix converter because through this self-acting Control of the bidirectional circuit breaker overvoltage is actively limited to a predetermined value. In this method according to the invention it does not matter which terminal of the matrix converter has an overvoltage occurs, but it is only interested that an overvoltage occurs. Once this is detected, all bidirectional circuit breakers will so controlled that this determined overvoltage actively limited becomes.

at an advantageous method is not the potentials at the Input and / or output terminals of the matrix converter evaluated, but the potentials of the control terminals of all bidirectional circuit breakers of the matrix converter. Thus, the advantageous method differs only by the place of detection of an overvoltage, but not in the active limit of a determined overvoltage.

A Active overvoltage protection device according to the invention has at least one rectifier circuit, at least one high voltage zener diode and at least one diode circuit having a plurality of high-blocking Diodes, each high-voltage zener diode on the cathode side each with an output of the rectifier circuit and the anode side is connected to an input of the diode network. The inputs of the Rectifier circuits are the input side with the input and / or Output terminals of the matrix converter or respectively with the input terminals and one of the three output ports linked to the matrix converter. The high-blocking diodes of the diode circuit are on the cathode side each with a control terminal of the bidirectional power switch of Matrix converter connected.

at an advantageous embodiment the active overvoltage protection device this is inverter-oriented. This means that all input and Output terminals the matrix converter with the inputs of a rectifier circuit are connected. Furthermore Only one high-voltage zener diode is needed, at its anode the input of the diode circuit is connected. Through this inverter-oriented Embodiment of the active overvoltage protection device only one high voltage zener diode is needed.

at a further advantageous embodiment of this advantageous embodiment the active overvoltage protection device are each three high-blocking diodes of the diode circuit by a diode network consisting of three low-blocking zener diodes and a high-blocking diode, replaced. The three low-barrier Zener diodes are on the anode side with the cathode of the high-blocking Diode connected to the anode side with the high voltage zener diode connected is. By this configuration, the number of high-blocking Diodes further reduced.

The embodiment the active overvoltage protection device can also be constructed phase-oriented, which then produces three high-voltage zener diodes and three rectifier circuits are needed. Also with this phase-oriented embodiment the active overvoltage protection device can in each case three high-blocking diodes of the diode circuit by a Diode network, consisting of three low-blocking zener diodes and a high-blocking diode, to be replaced.

In addition, can the inverter or phase oriented embodiment of the active overvoltage protection device dependent from the direction of the streams be divided in the matrix converter. That is, the active overvoltage protection device can phase or inverter oriented and for forward and reverse be built together or separately. Most high-voltage zener diodes, namely six pieces, be in a phase-oriented and back-and-forth direction separate embodiment second hand.

The choice of the design of the active overvoltage protection devices depends on the structure of the matrix converter. The bidirectional Circuit breakers can all be accommodated in one module. These can also be integrated in phase in each case in one module or on the network and load sides in each case in one module. By designing the structure of the active overvoltage protection device depending on the structure of the matrix converter, parts of the overvoltage protection device can be placed in the immediate vicinity of the modules of the converter. This results in a low-inductance connection of the active overvoltage protection device to the matrix converter.

to further explanation The invention is referred to the drawing, in which several embodiments an active overvoltage protection device according to the invention are illustrated schematically.

1 shows a circuit diagram of a bidirectional circuit breaker in common collector mode, the

2 shows a circuit diagram of a bidirectional circuit breaker in Common Emitter Mode, in which

3 is a circuit diagram of a bidirectional circuit breaker shown as an embedded switch, in the

4 a voltage clamping circuit for a semiconductor switch is shown, the

5 shows a circuit diagram of a matrix converter with bidirectional circuit breakers according to 1 , the

6 shows a circuit diagram of a matrix converter with bidirectional circuit breakers according to 3 , the

7 shows a converter-oriented embodiment of a first variant of the active overvoltage protection device according to the invention, wherein in

8th an advantageous embodiment of the active overvoltage device according to 7 is shown

9 shows a converter-oriented embodiment with back and forth separately the active overvoltage protection device according to the invention, the

10 shows an advantageous embodiment of the active overvoltage protection device according to 9 , where the

11 shows a phase-oriented embodiment of an overvoltage protection device according to the invention, wherein the

12 an advantageous embodiment of the phase-oriented embodiment of the active overvoltage protection device according to 11 show the

13 shows a phase-oriented embodiment with back and forth separately the active overvoltage protection device according to the invention, in the

14 is a converter-oriented embodiment of a second variant of the active overvoltage protection device according to the invention shown in more detail, wherein the

15 shows a converter-oriented embodiment of a second variant with forward and backward direction separated and in

16 is a phase-oriented embodiment of the second variant according to 14 shown in more detail.

In the 5 is a circuit of a matrix converter 28 shown, the nine bidirectional circuit breaker 2 in common collector mode. These bidirectional circuit breakers 2 are arranged in a 3 × 3 switch matrix. The emitter terminals of these bidirectional circuit breakers 2 form either an input terminal U or V or W or an output terminal X or Y or Z of the matrix converter 28 , At the input terminals U, V and W is a three-phase network 30 and at the output terminals X, Y and Z, a three-phase load 32 , in particular an induction machine, connected. The gate terminals G of the network-side half-circuit breaker 6 the bidirectional circuit breaker 2 are provided with an index N ', wherein the gate terminals G of the load-side semiconductor 4 this bidirectional circuit breaker 2 are provided with an index P '. A phase of the matrix converter 28 is an arrangement of three bidirectional circuit breakers 2 which establishes a connection from the three line-side terminals, U, V and W, to a respective load-side terminal X, Y and Z, respectively. For this reason, these gate terminals G are the bidirectional power switch 2 provided with two index numbers. In this equivalent circuit diagram of the matrix converter 28 with bidirectional circuit breakers 2 In Common Collector Mode, the anti-parallel diodes are the anti-serially connected semiconductor switches 4 and 6 the bidirectional circuit breaker 2 omitted for clarity.

In the 6 is this matrix converter 28 with bidirectional circuit breakers 2 shown in embedded mode. This matrix converter 28 is different from the matrix converter 28 according to 5 only through the topology of bidirectional circuit breakers 2 ,

To protect the matrix converter 28 Therefore, an overvoltage protection device is provided which has at least one rectifier circuit, at least one high-voltage zener diode and at least one diode circuit.

A first converter-oriented embodiment of a first variant of the active overvoltage device according to the invention is shown in FIG 7 shown in more detail. This overvoltage protection device has a rectifier circuit 34 , a high-voltage zener diode 10 , also referred to as a transiode diode, and a diode circuit 36 on. The rectifier circuit 34 has three diodes facing the mains side 18 and three load side facing diodes 16 on. The diodes 18 are on the anode side each with an input terminal U, V or W and the diodes 16 are each connected to an output terminal X, Y or Z of the matrix converter 28 connected. The diode circuit 36 has nine diodes 20 and nine diodes 22 on. The diodes 20 respectively. 22 are each the cathode side with gate terminals G of the bidirectional power switch 2 of the matrix converter 28 connected. The diodes 20 and 22 are on the anode side with the anode terminal of the Transildiode 10 linked, in turn, the cathode side with the cathode terminals of the diodes 16 and 18 the rectifier circuit 34 is electrically connected. Since the active overvoltage protection device only one rectifier circuit 34 and only a high voltage zener diode 10 has, this is constructed converter-oriented. This inverter-oriented active overvoltage protection device is advantageously used when the matrix converter 28 consists of a module.

In the 8th an advantageous embodiment of the first variant of the active overvoltage protection device is shown. This advantageous embodiment differs from the embodiment according to 7 in that instead of three high-blocking diodes 20 and 22 the diode circuit 36 one diode network each 38 and 40 is provided. Every diode network 38 . 40 consists of three low-blocking zener diodes 42 . 44 and a high-blocking diode 46 . 48 , The three low-blocking zener diodes 42 respectively. 44 are on the anode side with the cathode of high-blocking diodes 46 respectively. 48 linked, the anode side with the anode of the high voltage zener diode 10 is linked. By this configuration, the number of high-blocking diodes 20 respectively. 22 reduced from nine to three. This reduces the cost of the active overvoltage protection device.

The 9 shows a converter-oriented embodiment of the first variant of the active overvoltage protection device, wherein the forward and return are separated. Compared to the embodiment according to 7 are the rectifier circuit 34 and the diode circuit 36 each halved. That is, the diodes 18 and 16 the rectifier circuit 34 each form a partial rectifier circuit 50 and 52 whereas the diodes 20 and 22 the diode circuit 36 each a partial diode circuit 54 and 56 form. On the cathode side are the diodes 18 and 16 each with a cathode terminal of a transit diode 10 connected. On the anode side is each of these transiod diodes 10 with the anodes of the diodes 20 respectively. 22 the partial diode circuit 54 and 56 connected. This embodiment of the active overvoltage protection device is preferably used when the matrix converter 28 is realized by two modules, wherein in a module all network-side semiconductor switches 6 and in the other module, all load-side semiconductor switches 4 are integrated.

In the 10 is an advantageous embodiment of the embodiment according to 9 shown in more detail. In this variant, the number of high-blocking diodes 20 and 22 significantly reduced. Instead of nine high-blocking diodes each 20 and 22 the partial diode circuits 54 and 56 Now only three high-blocking diodes are 46 and 48 needed, each with three, low-blocking zener diodes 42 respectively. 44 are provided. Here is each high-blocking diode 46 respectively. 48 on the cathode side with an anode connection of three Zener diodes 42 respectively. 44 electrically connected, in turn, the cathode side with control terminals of the bidirectional power switch 2 of the matrix converter 28 are linked. By reducing the number of high-blocking diodes 46 and 48 can the diode circuit 36 be built even more space-saving. In addition, the cost of the active over-voltage protection device for the matrix converter is reduced 28 ,

In the 11 is a phase-oriented embodiment of an active overvoltage protection device according to the invention for a matrix converter 28 shown. This embodiment differs from the embodiment according to FIG 7 in that the rectifier circuit 34 and the diode circuit 36 each in three sub-rectifier circuits 58 . 60 and 62 and three sub-diode circuits 64 . 66 and 68 are divided. Each sub-rectifier circuit 58 . 60 and 62 is on the one hand with the input terminals U, V and W and one off gangs connection X or Y or Z of the matrix converter 28 connected. The partial diode circuits 64 . 66 and 68 are each with the control terminals of the bidirectional power switch 2 linked to a matrix converter phase. In this embodiment, the back and forth directions are as in the embodiment of FIG 7 not separated. The overvoltage protection device according to 11 is recommended if and only if the matrix converter 28 has one module per phase.

In the 12 is an advantageous embodiment of the embodiment according to 11 shown in more detail. Also in this advantageous embodiment, three high-blocking diodes each 20 and 22 the partial diode circuits 64 . 66 and 68 each through a diode network 38 respectively. 40 replaced, here only the diode network 40 each shown in more detail.

In the 13 a phase-oriented embodiment of the active overvoltage protection device according to the invention is shown, wherein the reciprocal direction of the matrix converter 28 are separated. This embodiment differs from the embodiment according to FIG 11 in that each sub-rectifier circuit 58 . 60 and 62 and each partial diode circuit 64 . 66 and 68 are halved. This only doubles the number of high-voltage zener diodes 10 ,

In the 14 is a converter-oriented embodiment of a second variant of the active overvoltage protection device according to the invention shown in more detail. The essential difference from the first variant is that the rectifier circuit 34 no longer on the input side with the input and output terminals U, V, W and X, Y, Z of the matrix converter 28 but with the control terminals G of the bidirectional power switch 2 of the matrix converter 28 , For this reason, now the rectifier circuit 34 eighteen high blocking diodes 16 and 18 on, which are all connected to each other on the cathode side. This node forms the output of the rectifier circuit 34 , The diode circuit 36 corresponds to the structure of the diode circuit 36 the embodiment of the active overvoltage protection device according to 7 , Thus, this first embodiment of the second variant of the active overvoltage protection device is also constructed converter-oriented. A corresponding phase-oriented embodiment of the second variant is in the 16 shown, wherein a converter-oriented with back and forth direction separated in the 15 is shown in more detail. These in the 14 to 16 illustrated embodiments of the second variant of the active overvoltage protection device can only in a matrix converter 28 be used, whose nine bidirectional circuit breakers 2 in the topology "common collector mode" or "common emitter mode" are executed. The use of this second variant of the active overvoltage protection device is in a matrix converter with bidirectional power switch 2 not possible in the "Embedded Mode" topology.

Characterized in that at least one high-voltage zener diode in common for all semiconductor switches 4 . 6 respectively. 5 the bidirectional circuit breaker 2 of the matrix converter 28 is used, is the expense of overvoltage protection of a matrix converter 28 minimal. The voltage limits for all semiconductor switches 4 . 6 respectively. 5 the bidirectional circuit breaker 2 In one inverter oriented embodiment, the active overvoltage protection device is implemented by a single high voltage zener diode 10 performed. By this active overvoltage protection device according to the invention is an occurring voltage in the matrix converter 28 determined, with the presence of an overvoltage Siert only interes and not the location of the overvoltage in the matrix converter 28 , A determined overvoltage results in that, in a converter-oriented embodiment of the active overvoltage protection device, all the semiconductor switches 4 . 6 or 5 the bidirectional circuit breaker 2 of the matrix converter 28 be controlled in such a way that they actively limit this overvoltage. Thus, the overvoltage protection is no longer for each individual semiconductor switch 4 . 6 respectively. 5 the bidirectional circuit breaker 2 or every single bidirectional circuit breaker 2 solved separately, but for the entire matrix converter 28 together.

Claims (6)

Method for protecting a matrix converter ( 28 ) against surges with nine bidirectional circuit breakers arranged in a 3 × 3 switch matrix ( 2 ), where either - from all input and output potentials ( 7 ) or - in each case from all input and output potentials ( 9 ) or - in each case from all input potentials and one of the three output potentials ( 11 ) a maximum potential is determined, wherein when a predetermined limit value is exceeded, the bidirectional power switches ( 2 ) of the matrix converter ( 28 ). Method according to Claim 1, in which, instead of the input and output potentials, control potentials of the bidirectional power switches ( 2 ) of the matrix converter ( 28 ) be used ( 14 ). Active overvoltage protection device for a matrix converter ( 28 ), the nine bidirectional power switches (3) arranged in a 3 × 3 switch matrix ( 2 ), with at least one rectifier circuit ( 34 . 50 . 52 . 58 . 60 . 62 ), at least one high voltage zener diode ( 10 ) and at least one diode circuit ( 36 . 54 . 56 . 64 . 66 . 68 ), each high-voltage zener diode ( 10 ) on the cathode side with an output of the rectifier circuit ( 34 . 50 . 52 . 58 . 60 . 62 ) and the anode side with an input of the diode circuit ( 36 . 54 . 56 . 64 . 66 . 68 ), the rectifier circuits ( 34 . 50 . 52 . 58 . 60 . 62 ) - on the input side with the input and / or output terminals (U, V, W, X, Y, Z) ( 7 . 9 ) or - are respectively linked to the input terminals (U, V, W) and one of the three output terminals (X, Y, Z) ( 11 ) and the outputs of the diode circuit ( 36 . 54 . 56 . 64 . 66 . 68 ) each with a control terminal of the bidirectional power switch ( 2 ) of the matrix converter ( 28 ) are connected. Active overvoltage protection device according to claim 3, wherein the diode circuit ( 36 . 54 . 56 . 64 . 66 . 68 ) only high-blocking diodes ( 20 . 22 ) having ( 7 ). Active overvoltage protection device according to claim 4, wherein in each case instead of three high-blocking diodes ( 20 . 22 ) of the diode circuit ( 36 . 54 . 56 . 64 . 66 . 68 ) three low-blocking zener diodes ( 42 . 44 ) and a high-blocking diode ( 46 . 48 ), wherein the low-blocking zener diodes ( 42 . 44 ) on the anode side with a cathode connection of the high-blocking diode ( 46 . 48 ) are linked ( 8th ). Active overvoltage protection device according to one of claims 3 to 5, wherein each rectifier circuit ( 34 . 50 . 52 . 58 . 60 . 62 ) several high-blocking diodes ( 16 . 18 ) whose cathode terminals are connected together to form an output of a rectifier circuit ( 34 . 50 . 52 . 58 . 60 . 62 ) are connected.